Stopper Cylinder D Lever type models Caution RS (D) 32/40/50-L RS (D) 32/40/50-B RS (D) 32/40/50-C RS (D) 32/40/50-D RS (D) 32/40/50-E Mounting base 1. Do not allow a pallet to collide with the cylinder when the lever is upright.
12, 16 ) Note 2) 2 (Different surfaces, Same surface) 1 85 90 95 D-M9 D-M9W (n 2) 2 15 80 80 + 40 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 85 + 40 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 90 + 40 (n 4) 2 95 + 40 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 15 + 40 n (n = 2, 4, 6, 8 ) Note 1) (n = 4, 8, 12, 16 ) Note 2) 2 (Different surfaces, Same surface) 1 60 65 70 D-M9V D-M9WV (n 2) 2 10 55 55 + 30
Drain gu de T14 AFD3O 40 NPT Flow d reclon B ghl10 left AFD20 to 40 Drain cock w lh barb flling: AFD30. 40 Nore 1)Drain !!
AR20K tJ 60K AB1010 40.
48 30 40 48 15 15 20 24 15 20 24 62.5 73.5 72 75 78 76.5 79.5 30 35 35 35 40 40 40 9 9 9 20 22 22 22 24.5 24.5 24.5 8 8 9 14 8 9 14 15 15 22.2 19 15 22.2 19 18 18 22.2 20.6 18 22.2 20.6 6.4 6.4 7.6 6 6.4 7.6 6 27 29.5 29.5 29.5 32 32 32 44 54 52.5 53.5 58 56.5 57.5 30 32.5 32.5 32.5 35 35 35 30.5 40 38.5 39.5 44.5 43 44 2 11 9 9 3 11 Conduit terminal DIN terminal Size Port size P Q R S Q
VCA20/30/40 Single unit Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com 17-2-14 VV2CA2/3/4 Manifold N.C. VCB20/30/40 17-2-24 Single unit N.C. 17-2-32 VCL20/30/40 N.C. Single unit VV2CL2/3/4 17-2-36 N.C.
Hmm 0.3MPa 0.7MPa 0.3MPa 60 0.7MPa 0.4MPa 60 0.4MPa 40 40 20 20 100 80 60 40 20 0 100 0 80 60 40 20 Gripping point L mm Gripping point L mm 12-3-6 7 Model Selection Series MHF2 Confirmation of External Force on Fingers: Series MHF2 Step 3 MHZ L L MHF MHL Mr Mp Fv My MHR MHK MHS L MHC MHT MHY L: Distance to the point at which the load is applied (mm) MHW Maximum allowable moment Allowable
60 40 20 0 0 50 30 10 Gripping point L mm Gripping point L mm MHF2-16D MHF2-20D 100 0.5MPa 100 Pressure 0.2MPa Pressure 0.2MPa 80 0.5MPa 0.6MPa 80 0.6MPa Overhang Hmm Overhang Hmm 0.3MPa 0.7MPa 0.3MPa 60 0.7MPa 0.4MPa 60 0.4MPa 40 40 20 20 100 80 60 40 20 0 100 80 60 40 20 0 Gripping point L mm Gripping point L mm 12-3-6 7 Model Selection Series MHF2 Confirmation of External Force on Fingers
Hmm 0.7MPa 0.3MPa 0.3MPa 60 0.7MPa 60 0.4MPa 0.4MPa 40 40 20 20 100 80 60 40 20 0 80 60 40 20 0 100 Gripping point L mm Gripping point L mm 3 Series MHF2 Confirmation of external force on fingers: Series MHF2 Step 3 L L Mr Mp Fv My L L: Distance to the point at which the load is applied (mm) Maximum allowable moment Allowable vertical load Fv (N) Model Pitch moment Mp (Nm) Yaw moment My(
AW20 (K) to 40 (KJ !
dual stroke with 3 position (single rod type) ; XC12 is tandem dual force cylinder ; Bore sizes (mm): 20, 25, 32, 40 ; Variety of switches and lead wire lengths
with 3 position (single rod type); XC12 is tandem dual force cylinder; Bore sizes (mm): 20, 25, 32, 40; Variety of switches and lead wire lengths
dual stroke with 3 position (single rod type) ; XC12 is tandem dual force cylinder ; Bore sizes (mm): 20, 25, 32, 40 ; Variety of switches and lead wire lengths
50 60 3 2 6 30 60 8 25 35 10 20 40 10 35 Flow rate Q kg/h Figures inside [ ] indicate the saturated steam holding heat (kcal/kg).
This is a legacy product. Please contact us for the latest version.sales@ocaire.com
Magnet: Built-in Magnet, Mounting: Standard, Through-hole, Bore Size: 32mm, Stroke 1: 40mm, +: +, Stroke 2: 10mm, Body Option: Standard, Rod End Female Thead, Auto Switch Groove: ø12 to ø25, 2 Surfaces; ø32 to ø100, 4 Surfaces, Auto Switch: No Switch, Lead Wire or Prewired Connector: 0.5m (Or None in the Case of No Switch), Number: 2 pcs. (Or None in the Case of No Switch), Stroke Options
This is a legacy product. Please contact us for the latest version.sales@ocaire.com
(lmm) mm Nm mm MHY2-10D M3x0.5 0.88 6 11H9 1.5 MHY2-16D M4x0.7 2.1 8 17H9 1.5 MHY2-20D M5x0.8 4.3 10 21H9 1.5 MHY2-25D M6x1 7.3 12 26H9 1.5 Nm (lmm) MHY2-10D M3x0.5 0.88 6 MHY2-16D M4x0.7 2.1 8 MHY2-20D M5x0.8 4.3 10 MHY2-25D M6x1 7.3 12 8 Nm (lmm) MHY2-10D M3x0.5 0.88 6 MHY2-16D M4x0.7 2.1 8 MHY2-20D M5x0.8 4.3 10 MHY2-25D M6x1 7.4 12 Nm{kgfcm} MHY2-10D M3x0.5 0.88{9} MHY2-16D M4x0.7 2.1
Next, measure this flow rate at 80%, 60%, 40%, and 20%, as well as the upstream and downstream pressure. The sonic conductance C can be calculated based on this maximum flow rate. Substitute the data of the others into the subsonic flow formula to find b, and calculate the critical pressure ratio b from that average.